基于云的人工智能和图谱模型的自动分割准确性评估。

Evaluation of auto-segmentation accuracy of cloud-based artificial intelligence and atlas-based models.

机构信息

Department of Radiological Sciences, Graduate School of Human Health Sciences, Tokyo Metropolitan University, 7-2-10 Higashi-Ogu, Arakawa-ku, Tokyo, 116-8551, Japan.

Department of Medical Physics, National Cancer Center Hospital, 5-1-1 Tsukiji, Chuo-ku, Tokyo, 104-0045, Japan.

出版信息

Radiat Oncol. 2021 Sep 9;16(1):175. doi: 10.1186/s13014-021-01896-1.

DOI:10.1186/s13014-021-01896-1

PMID:34503533

原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC8427857/

Abstract

BACKGROUND

Contour delineation, a crucial process in radiation oncology, is time-consuming and inaccurate due to inter-observer variation has been a critical issue in this process. An atlas-based automatic segmentation was developed to improve the delineation efficiency and reduce inter-observer variation. Additionally, automated segmentation using artificial intelligence (AI) has recently become available. In this study, auto-segmentations by atlas- and AI-based models for Organs at Risk (OAR) in patients with prostate and head and neck cancer were performed and delineation accuracies were evaluated.

METHODS

Twenty-one patients with prostate cancer and 30 patients with head and neck cancer were evaluated. MIM Maestro was used to apply the atlas-based segmentation. MIM Contour ProtégéAI was used to apply the AI-based segmentation. Three similarity indices, the Dice similarity coefficient (DSC), Hausdorff distance (HD), and mean distance to agreement (MDA), were evaluated and compared with manual delineations. In addition, radiation oncologists visually evaluated the delineation accuracies.

RESULTS

Among patients with prostate cancer, the AI-based model demonstrated higher accuracy than the atlas-based on DSC, HD, and MDA for the bladder and rectum. Upon visual evaluation, some errors were observed in the atlas-based delineations when the boundary between the small bowel or the seminal vesicle and the bladder was unclear. For patients with head and neck cancer, no significant differences were observed between the two models for almost all OARs, except small delineations such as the optic chiasm and optic nerve. The DSC tended to be lower when the HD and the MDA were smaller in small volume delineations.

CONCLUSIONS

In terms of efficiency, the processing time for head and neck cancers was much shorter than manual delineation. While quantitative evaluation with AI-based segmentation was significantly more accurate than atlas-based for prostate cancer, there was no significant difference for head and neck cancer. According to the results of visual evaluation, less necessity of manual correction in AI-based segmentation indicates that the segmentation efficiency of AI-based model is higher than that of atlas-based model. The effectiveness of the AI-based model can be expected to improve the segmentation efficiency and to significantly shorten the delineation time.

摘要

背景

轮廓勾画是放射肿瘤学中的一个关键过程，但由于观察者间的差异，这个过程耗时且不准确，一直是一个关键问题。基于图谱的自动分割被开发出来，以提高勾画效率并减少观察者间的差异。此外，基于人工智能的自动分割最近也已经可用。在这项研究中，我们对前列腺癌和头颈部癌症患者的危及器官（OAR）进行了基于图谱和基于人工智能的自动分割，并评估了勾画的准确性。

方法

评估了 21 例前列腺癌患者和 30 例头颈部癌症患者。使用 MIM Maestro 进行基于图谱的分割。使用 MIM Contour Protégé AI 进行基于人工智能的分割。评估了三个相似性指数，即 Dice 相似系数（DSC）、Hausdorff 距离（HD）和平均一致性距离（MDA），并与手动勾画进行了比较。此外，放射肿瘤学家对勾画的准确性进行了视觉评估。

结果

在前列腺癌患者中，对于膀胱和直肠，基于人工智能的模型在 DSC、HD 和 MDA 方面比基于图谱的模型具有更高的准确性。在视觉评估中，当小肠或精囊与膀胱之间的边界不清晰时，基于图谱的勾画会出现一些错误。对于头颈部癌症患者，除了视神经和视交叉等小体积勾画外，两种模型在几乎所有 OAR 方面都没有显著差异。在小体积勾画中，当 HD 和 MDA 较小时，DSC 往往较低。

结论

在效率方面，头颈部癌症的处理时间比手动勾画要短得多。虽然基于人工智能的分割在前列腺癌方面的定量评估明显比基于图谱的更准确，但对头颈部癌症则没有显著差异。根据视觉评估的结果，基于人工智能的分割需要手动校正的情况较少，表明人工智能模型的分割效率高于基于图谱的模型。基于人工智能的模型的有效性有望提高分割效率，并显著缩短勾画时间。

https://cdn.ncbi.nlm.nih.gov/pmc/blobs/10bb/8427857/5d5e32fd57c2/13014_2021_1896_Fig1_HTML.jpg

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基于云的人工智能和图谱模型的自动分割准确性评估。

Evaluation of auto-segmentation accuracy of cloud-based artificial intelligence and atlas-based models.

机构信息

出版信息

BACKGROUND

METHODS

RESULTS

CONCLUSIONS

背景

方法

结果

结论

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